lib/CodeGen/AsmPrinter/DwarfAccelTable.h - platform/external/llvm - Git at Google

 //==-- llvm/CodeGen/DwarfAccelTable.h - Dwarf Accelerator Tables -*- C++ -*-==//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file contains support for writing dwarf accelerator tables.
 //
 //===----------------------------------------------------------------------===//

 #ifndef CODEGEN_ASMPRINTER_DWARFACCELTABLE_H__
 #define CODEGEN_ASMPRINTER_DWARFACCELTABLE_H__

 #include "DIE.h"
 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/StringMap.h"
 #include "llvm/MC/MCSymbol.h"
 #include "llvm/Support/DataTypes.h"
 #include "llvm/Support/Debug.h"
 #include "llvm/Support/Dwarf.h"
 #include "llvm/Support/ErrorHandling.h"
 #include "llvm/Support/Format.h"
 #include "llvm/Support/FormattedStream.h"
 #include <map>
 #include <vector>

 // The dwarf accelerator tables are an indirect hash table optimized
 // for null lookup rather than access to known data. They are output into
 // an on-disk format that looks like this:
 //
 // .-------------.
 // |  HEADER     |
 // |-------------|
 // |  BUCKETS    |
 // |-------------|
 // |  HASHES     |
 // |-------------|
 // |  OFFSETS    |
 // |-------------|
 // |  DATA       |
 // `-------------'
 //
 // where the header contains a magic number, version, type of hash function,
 // the number of buckets, total number of hashes, and room for a special
 // struct of data and the length of that struct.
 //
 // The buckets contain an index (e.g. 6) into the hashes array. The hashes
 // section contains all of the 32-bit hash values in contiguous memory, and
 // the offsets contain the offset into the data area for the particular
 // hash.
 //
 // For a lookup example, we could hash a function name and take it modulo the
 // number of buckets giving us our bucket. From there we take the bucket value
 // as an index into the hashes table and look at each successive hash as long
 // as the hash value is still the same modulo result (bucket value) as earlier.
 // If we have a match we look at that same entry in the offsets table and
 // grab the offset in the data for our final match.

 namespace llvm {

 class AsmPrinter;
 class DIE;
 class DwarfUnits;

 class DwarfAccelTable {

   enum HashFunctionType {
     eHashFunctionDJB = 0u
   };

   static uint32_t HashDJB (StringRef Str) {
     uint32_t h = 5381;
     for (unsigned i = 0, e = Str.size(); i != e; ++i)
       h = ((h << 5) + h) + Str[i];
     return h;
   }

   // Helper function to compute the number of buckets needed based on
   // the number of unique hashes.
   void ComputeBucketCount (void);

   struct TableHeader {
     uint32_t   magic;           // 'HASH' magic value to allow endian detection
     uint16_t   version;         // Version number.
     uint16_t   hash_function;   // The hash function enumeration that was used.
     uint32_t   bucket_count;    // The number of buckets in this hash table.
     uint32_t   hashes_count;    // The total number of unique hash values
                                 // and hash data offsets in this table.
     uint32_t   header_data_len; // The bytes to skip to get to the hash
                                 // indexes (buckets) for correct alignment.
     // Also written to disk is the implementation specific header data.

     static const uint32_t MagicHash = 0x48415348;

     TableHeader (uint32_t data_len) :
       magic (MagicHash), version (1), hash_function (eHashFunctionDJB),
       bucket_count (0), hashes_count (0), header_data_len (data_len)
     {}

 #ifndef NDEBUG
     void print(raw_ostream &O) {
       O << "Magic: " << format("0x%x", magic) << "\n"
         << "Version: " << version << "\n"
         << "Hash Function: " << hash_function << "\n"
         << "Bucket Count: " << bucket_count << "\n"
         << "Header Data Length: " << header_data_len << "\n";
     }
     void dump() { print(dbgs()); }
 #endif
   };

 public:
   // The HeaderData describes the form of each set of data. In general this
   // is as a list of atoms (atom_count) where each atom contains a type
   // (AtomType type) of data, and an encoding form (form). In the case of
   // data that is referenced via DW_FORM_ref_* the die_offset_base is
   // used to describe the offset for all forms in the list of atoms.
   // This also serves as a public interface of sorts.
   // When written to disk this will have the form:
   //
   // uint32_t die_offset_base
   // uint32_t atom_count
   // atom_count Atoms
   enum AtomType {
     eAtomTypeNULL       = 0u,
     eAtomTypeDIEOffset  = 1u,   // DIE offset, check form for encoding
     eAtomTypeCUOffset   = 2u,   // DIE offset of the compiler unit header that
                                 // contains the item in question
     eAtomTypeTag        = 3u,   // DW_TAG_xxx value, should be encoded as
                                 // DW_FORM_data1 (if no tags exceed 255) or
                                 // DW_FORM_data2.
     eAtomTypeNameFlags  = 4u,   // Flags from enum NameFlags
     eAtomTypeTypeFlags  = 5u    // Flags from enum TypeFlags
   };

   enum TypeFlags {
     eTypeFlagClassMask = 0x0000000fu,

     // Always set for C++, only set for ObjC if this is the
     // @implementation for a class.
     eTypeFlagClassIsImplementation  = ( 1u << 1 )
   };

   // Make these public so that they can be used as a general interface to
   // the class.
   struct Atom {
     AtomType type; // enum AtomType
     uint16_t form; // DWARF DW_FORM_ defines

     Atom(AtomType type, uint16_t form) : type(type), form(form) {}
     static const char * AtomTypeString(enum AtomType);
 #ifndef NDEBUG
     void print(raw_ostream &O) {
       O << "Type: " << AtomTypeString(type) << "\n"
         << "Form: " << dwarf::FormEncodingString(form) << "\n";
     }
     void dump() {
       print(dbgs());
     }
 #endif
   };

  private:
   struct TableHeaderData {
     uint32_t die_offset_base;
     SmallVector<Atom, 1> Atoms;

     TableHeaderData(ArrayRef<Atom> AtomList, uint32_t offset = 0)
       : die_offset_base(offset), Atoms(AtomList.begin(), AtomList.end()) { }

 #ifndef NDEBUG
     void print (raw_ostream &O) {
       O << "die_offset_base: " << die_offset_base << "\n";
       for (size_t i = 0; i < Atoms.size(); i++)
         Atoms[i].print(O);
     }
     void dump() {
       print(dbgs());
     }
 #endif
   };

   // The data itself consists of a str_offset, a count of the DIEs in the
   // hash and the offsets to the DIEs themselves.
   // On disk each data section is ended with a 0 KeyType as the end of the
   // hash chain.
   // On output this looks like:
   // uint32_t str_offset
   // uint32_t hash_data_count
   // HashData[hash_data_count]
 public:
   struct HashDataContents {
     DIE *Die; // Offsets
     char Flags; // Specific flags to output

     HashDataContents(DIE *D, char Flags) :
       Die(D),
       Flags(Flags) { }
     #ifndef NDEBUG
     void print(raw_ostream &O) const {
       O << "  Offset: " << Die->getOffset() << "\n";
       O << "  Tag: " << dwarf::TagString(Die->getTag()) << "\n";
       O << "  Flags: " << Flags << "\n";
     }
     #endif
   };
 private:
   struct HashData {
     StringRef Str;
     uint32_t HashValue;
     MCSymbol *Sym;
     ArrayRef<HashDataContents*> Data; // offsets
     HashData(StringRef S, ArrayRef<HashDataContents*> Data)
       : Str(S), Data(Data) {
       HashValue = DwarfAccelTable::HashDJB(S);
     }
     #ifndef NDEBUG
     void print(raw_ostream &O) {
       O << "Name: " << Str << "\n";
       O << "  Hash Value: " << format("0x%x", HashValue) << "\n";
       O << "  Symbol: " ;
       if (Sym) Sym->print(O);
       else O << "<none>";
       O << "\n";
       for (size_t i = 0; i < Data.size(); i++) {
         O << "  Offset: " << Data[i]->Die->getOffset() << "\n";
         O << "  Tag: " << dwarf::TagString(Data[i]->Die->getTag()) << "\n";
         O << "  Flags: " << Data[i]->Flags << "\n";
       }
     }
     void dump() {
       print(dbgs());
     }
     #endif
   };

   DwarfAccelTable(const DwarfAccelTable&) LLVM_DELETED_FUNCTION;
   void operator=(const DwarfAccelTable&) LLVM_DELETED_FUNCTION;

   // Internal Functions
   void EmitHeader(AsmPrinter *);
   void EmitBuckets(AsmPrinter *);
   void EmitHashes(AsmPrinter *);
   void EmitOffsets(AsmPrinter *, MCSymbol *);
   void EmitData(AsmPrinter *, DwarfUnits *D);

   // Allocator for HashData and HashDataContents.
   BumpPtrAllocator Allocator;

   // Output Variables
   TableHeader Header;
   TableHeaderData HeaderData;
   std::vector<HashData*> Data;

   // String Data
   typedef std::vector<HashDataContents*> DataArray;
   typedef StringMap<DataArray, BumpPtrAllocator&> StringEntries;
   StringEntries Entries;

   // Buckets/Hashes/Offsets
   typedef std::vector<HashData*> HashList;
   typedef std::vector<HashList> BucketList;
   BucketList Buckets;
   HashList Hashes;

   // Public Implementation
  public:
   DwarfAccelTable(ArrayRef<DwarfAccelTable::Atom>);
   ~DwarfAccelTable();
   void AddName(StringRef, DIE*, char = 0);
   void FinalizeTable(AsmPrinter *, const char *);
   void Emit(AsmPrinter *, MCSymbol *, DwarfUnits *);
 #ifndef NDEBUG
   void print(raw_ostream &O);
   void dump() { print(dbgs()); }
 #endif
 };

 }
 #endif
	//==-- llvm/CodeGen/DwarfAccelTable.h - Dwarf Accelerator Tables -- C++ --==//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains support for writing dwarf accelerator tables.
	//
	//===----------------------------------------------------------------------===//

	#ifndef CODEGEN_ASMPRINTER_DWARFACCELTABLE_H__
	#define CODEGEN_ASMPRINTER_DWARFACCELTABLE_H__

	#include "DIE.h"
	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/StringMap.h"
	#include "llvm/MC/MCSymbol.h"
	#include "llvm/Support/DataTypes.h"
	#include "llvm/Support/Debug.h"
	#include "llvm/Support/Dwarf.h"
	#include "llvm/Support/ErrorHandling.h"
	#include "llvm/Support/Format.h"
	#include "llvm/Support/FormattedStream.h"
	#include <map>
	#include <vector>

	// The dwarf accelerator tables are an indirect hash table optimized
	// for null lookup rather than access to known data. They are output into
	// an on-disk format that looks like this:
	//
	// .-------------.
	// \| HEADER \|
	// \|-------------\|
	// \| BUCKETS \|
	// \|-------------\|
	// \| HASHES \|
	// \|-------------\|
	// \| OFFSETS \|
	// \|-------------\|
	// \| DATA \|
	// `-------------'
	//
	// where the header contains a magic number, version, type of hash function,
	// the number of buckets, total number of hashes, and room for a special
	// struct of data and the length of that struct.
	//
	// The buckets contain an index (e.g. 6) into the hashes array. The hashes
	// section contains all of the 32-bit hash values in contiguous memory, and
	// the offsets contain the offset into the data area for the particular
	// hash.
	//
	// For a lookup example, we could hash a function name and take it modulo the
	// number of buckets giving us our bucket. From there we take the bucket value
	// as an index into the hashes table and look at each successive hash as long
	// as the hash value is still the same modulo result (bucket value) as earlier.
	// If we have a match we look at that same entry in the offsets table and
	// grab the offset in the data for our final match.

	namespace llvm {

	class AsmPrinter;
	class DIE;
	class DwarfUnits;

	class DwarfAccelTable {

	enum HashFunctionType {
	eHashFunctionDJB = 0u
	};

	static uint32_t HashDJB (StringRef Str) {
	uint32_t h = 5381;
	for (unsigned i = 0, e = Str.size(); i != e; ++i)
	h = ((h << 5) + h) + Str[i];
	return h;
	}

	// Helper function to compute the number of buckets needed based on
	// the number of unique hashes.
	void ComputeBucketCount (void);

	struct TableHeader {
	uint32_t magic; // 'HASH' magic value to allow endian detection
	uint16_t version; // Version number.
	uint16_t hash_function; // The hash function enumeration that was used.
	uint32_t bucket_count; // The number of buckets in this hash table.
	uint32_t hashes_count; // The total number of unique hash values
	// and hash data offsets in this table.
	uint32_t header_data_len; // The bytes to skip to get to the hash
	// indexes (buckets) for correct alignment.
	// Also written to disk is the implementation specific header data.

	static const uint32_t MagicHash = 0x48415348;

	TableHeader (uint32_t data_len) :
	magic (MagicHash), version (1), hash_function (eHashFunctionDJB),
	bucket_count (0), hashes_count (0), header_data_len (data_len)
	{}

	#ifndef NDEBUG
	void print(raw_ostream &O) {
	O << "Magic: " << format("0x%x", magic) << "\n"
	<< "Version: " << version << "\n"
	<< "Hash Function: " << hash_function << "\n"
	<< "Bucket Count: " << bucket_count << "\n"
	<< "Header Data Length: " << header_data_len << "\n";
	}
	void dump() { print(dbgs()); }
	#endif
	};

	public:
	// The HeaderData describes the form of each set of data. In general this
	// is as a list of atoms (atom_count) where each atom contains a type
	// (AtomType type) of data, and an encoding form (form). In the case of
	// data that is referenced via DW_FORM_ref_* the die_offset_base is
	// used to describe the offset for all forms in the list of atoms.
	// This also serves as a public interface of sorts.
	// When written to disk this will have the form:
	//
	// uint32_t die_offset_base
	// uint32_t atom_count
	// atom_count Atoms
	enum AtomType {
	eAtomTypeNULL = 0u,
	eAtomTypeDIEOffset = 1u, // DIE offset, check form for encoding
	eAtomTypeCUOffset = 2u, // DIE offset of the compiler unit header that
	// contains the item in question
	eAtomTypeTag = 3u, // DW_TAG_xxx value, should be encoded as
	// DW_FORM_data1 (if no tags exceed 255) or
	// DW_FORM_data2.
	eAtomTypeNameFlags = 4u, // Flags from enum NameFlags
	eAtomTypeTypeFlags = 5u // Flags from enum TypeFlags
	};

	enum TypeFlags {
	eTypeFlagClassMask = 0x0000000fu,

	// Always set for C++, only set for ObjC if this is the
	// @implementation for a class.
	eTypeFlagClassIsImplementation = ( 1u << 1 )
	};

	// Make these public so that they can be used as a general interface to
	// the class.
	struct Atom {
	AtomType type; // enum AtomType
	uint16_t form; // DWARF DW_FORM_ defines

	Atom(AtomType type, uint16_t form) : type(type), form(form) {}
	static const char * AtomTypeString(enum AtomType);
	#ifndef NDEBUG
	void print(raw_ostream &O) {
	O << "Type: " << AtomTypeString(type) << "\n"
	<< "Form: " << dwarf::FormEncodingString(form) << "\n";
	}
	void dump() {
	print(dbgs());
	}
	#endif
	};

	private:
	struct TableHeaderData {
	uint32_t die_offset_base;
	SmallVector<Atom, 1> Atoms;

	TableHeaderData(ArrayRef<Atom> AtomList, uint32_t offset = 0)
	: die_offset_base(offset), Atoms(AtomList.begin(), AtomList.end()) { }

	#ifndef NDEBUG
	void print (raw_ostream &O) {
	O << "die_offset_base: " << die_offset_base << "\n";
	for (size_t i = 0; i < Atoms.size(); i++)
	Atoms[i].print(O);
	}
	void dump() {
	print(dbgs());
	}
	#endif
	};

	// The data itself consists of a str_offset, a count of the DIEs in the
	// hash and the offsets to the DIEs themselves.
	// On disk each data section is ended with a 0 KeyType as the end of the
	// hash chain.
	// On output this looks like:
	// uint32_t str_offset
	// uint32_t hash_data_count
	// HashData[hash_data_count]
	public:
	struct HashDataContents {
	DIE *Die; // Offsets
	char Flags; // Specific flags to output

	HashDataContents(DIE *D, char Flags) :
	Die(D),
	Flags(Flags) { }
	#ifndef NDEBUG
	void print(raw_ostream &O) const {
	O << " Offset: " << Die->getOffset() << "\n";
	O << " Tag: " << dwarf::TagString(Die->getTag()) << "\n";
	O << " Flags: " << Flags << "\n";
	}
	#endif
	};
	private:
	struct HashData {
	StringRef Str;
	uint32_t HashValue;
	MCSymbol *Sym;
	ArrayRef<HashDataContents*> Data; // offsets
	HashData(StringRef S, ArrayRef<HashDataContents*> Data)
	: Str(S), Data(Data) {
	HashValue = DwarfAccelTable::HashDJB(S);
	}
	#ifndef NDEBUG
	void print(raw_ostream &O) {
	O << "Name: " << Str << "\n";
	O << " Hash Value: " << format("0x%x", HashValue) << "\n";
	O << " Symbol: " ;
	if (Sym) Sym->print(O);
	else O << "<none>";
	O << "\n";
	for (size_t i = 0; i < Data.size(); i++) {
	O << " Offset: " << Data[i]->Die->getOffset() << "\n";
	O << " Tag: " << dwarf::TagString(Data[i]->Die->getTag()) << "\n";
	O << " Flags: " << Data[i]->Flags << "\n";
	}
	}
	void dump() {
	print(dbgs());
	}
	#endif
	};

	DwarfAccelTable(const DwarfAccelTable&) LLVM_DELETED_FUNCTION;
	void operator=(const DwarfAccelTable&) LLVM_DELETED_FUNCTION;

	// Internal Functions
	void EmitHeader(AsmPrinter *);
	void EmitBuckets(AsmPrinter *);
	void EmitHashes(AsmPrinter *);
	void EmitOffsets(AsmPrinter , MCSymbol );
	void EmitData(AsmPrinter , DwarfUnits D);

	// Allocator for HashData and HashDataContents.
	BumpPtrAllocator Allocator;

	// Output Variables
	TableHeader Header;
	TableHeaderData HeaderData;
	std::vector<HashData*> Data;

	// String Data
	typedef std::vector<HashDataContents*> DataArray;
	typedef StringMap<DataArray, BumpPtrAllocator&> StringEntries;
	StringEntries Entries;

	// Buckets/Hashes/Offsets
	typedef std::vector<HashData*> HashList;
	typedef std::vector<HashList> BucketList;
	BucketList Buckets;
	HashList Hashes;

	// Public Implementation
	public:
	DwarfAccelTable(ArrayRef<DwarfAccelTable::Atom>);
	~DwarfAccelTable();
	void AddName(StringRef, DIE*, char = 0);
	void FinalizeTable(AsmPrinter , const char );
	void Emit(AsmPrinter , MCSymbol , DwarfUnits *);
	#ifndef NDEBUG
	void print(raw_ostream &O);
	void dump() { print(dbgs()); }
	#endif
	};

	}
	#endif